An aluminium battery operating with an aqueous electrolyte

Holland, Alexander; McKerracher, R. D.; Cruden, Andrew; Wills, Richard

doi:10.1007/s10800-018-1154-x

Cited by 78 publications

(59 citation statements)

References 20 publications

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“…Holland et al. initially found poor specific capacities for TiO 2 particles (actual 10 mAh g −1 vs. theoretical 335 mAh g −1 ), leading them to propose that the reaction TiO 2 + x Al 3+ +3 x e − ⇄Al x TiO 2 occurs only on surface sites . Lahan and Das later demonstrated this low specific capacity to be an artefact of poor electronic percolation within the active material, that is, they were able to achieve an enhanced capacity (52 mAh g −1 ) by compositing TiO 2 nanoparticles with conductivity‐enhancing graphite, and confirmed lattice changes to match with Al 2 TiO 5 and Al 2 Ti 7 O 15 phases through XRD and TEM analyses …”

Section: Trends In Enabling Aqueous Electrolytes For Multivalent‐ion mentioning

confidence: 99%

“…On a per ion basis, this would be a charge vector superior to that of elemental lithium . Indeed, transposing concepts from the aqueous lithium system to other water‐based chemistries, recent reports have demonstrated remarkable breakthroughs with heavier elements, for example, Na, Mg, Al, K, Ca, Cu, Fe, Zn, Mn, Rb/Tl, and V . We aim to contribute insights to push these further, by focusing on low‐cost, multivalent‐ion (Mg, Ca, Zn, Al) battery development from an electrolyte point of view.…”

Section: Introductionmentioning

confidence: 99%

“…However, because stored electrochemical energy is released as ap roduct of voltage, current, and time, and the voltage stability of free water is severely limited, aqueous batteries inspire efforts to achieve high-energyb atteries by drastically increasing charge capacitya tm oderate voltages, rathert han by creating > 5V cell systems.One methodi st or eplacet he monovalent-ion shuttlew ith a multivalent-ion shuttle to effect multiple electron-transfer events per ion crossover.O naper ion basis, this would be a charge vector superior to that of elemental lithium. [7] Indeed, transposing concepts from the aqueous lithium system to other water-based chemistries, recent reports have demonstrated remarkable breakthroughs with heaviere lements, for example, Na, [8] Mg, [9] Al, [10] K, [11] Ca, [12] Cu, [13] Fe, [14] Zn, [15] Mn, [16] Rb/Tl, [17] and V. [18] We aim to contribute insights to push these [a] Dr.…”

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confidence: 99%

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Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

et al. 2019

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Multivalent‐ion batteries built on water‐based electrolytes represent energy storage at suitable price points, competitive performance, and enhanced safety. However, to comply with modern energy‐density requirements, the battery must be reversible within an operating voltage window greater than 1.23 V or the electrochemical stability limits of free water. Taking advantage of its powerful solvation and catalytic activities, adding water to electrolyte preparations can unlock a wider gamut of liquid mixtures compared with strictly nonaqueous systems. However, a point‐by‐point sweep of all potential formulations is arduous and ineffective without some form of systematic rationalization. The present Review consolidates recent progress, pitfalls, limits, and insights critical to expediting aqueous electrolyte designs to boost multivalent‐ion battery outputs.

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Section: Trends In Enabling Aqueous Electrolytes For Multivalent‐ion mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

et al. 2019

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“…Recently, Gao and co‐workers reported that a type of copper‐hexacyanoferrate (CuHCF) has been synthesized, delivering a capacity of 41 mAh g −1 at 400 mA g −1 in 0.5 m Al 2 (SO 4 ) 3 aqueous electrolyte with acceptable capacity retention of 55 % after 1000 cycles . Wills and co‐workers also illustrated the availability of CuHCF as cathode material for aluminum‐ion batteries with an energy density of 15 mW h g −1 at a power density of 300 mW g −1 . Menke and co‐workers described CuHCF as a cathode material for aluminum‐ion batteries in an organic electrolyte, which delivered a reversible capacity of approximately 10 mA h g −1 at 50 μA cm −2 …”

Section: Introductionmentioning

confidence: 99%

The Compensation Effect Mechanism of Fe–Ni Mixed Prussian Blue Analogues in Aqueous Rechargeable Aluminum‐Ion Batteries

et al. 2020

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An aluminum‐ion battery was assembled with potassium nickel hexacyanoferrate (KNHCF) as a cathode and Al foil as an anode in aqueous electrolyte for the first time, based on Al3+ intercalation and deintercalation. A combination of ex situ XRD, X‐ray photoelectron spectroscopy (XPS), galvanostatic intermittent titration technique (GITT), and differential capacity analysis was used to unveil the crystal structure changes and the insertion/extraction mechanism of Al3+. Al3+ could reversibly insert/extract into/from KNHCF nanoparticles through a single‐phase reaction with reduction/oxidation of Fe and Ni. Over long‐term cycling, it was Fe rather than Ni that contributed to more capacity owing to the dissolution of Ni from the KNHCF structure, which could be expressed as a compensation effect of mixed redox centers in KNHCF. KNHCF delivered an initial discharge capacity of 46.5 mAh g−1. The capacity decay could be attributed to the unstable interface between Al foil and the aqueous electrolyte owing to the catalytic activity of the Ni transferring from Ni dissolution of KNHCF to the Al foil anode, rather than KNHCF structure collapse; KNHCF maintained its 3 D framework structure for 500 cycles. This work is expected to inspire more exhaustive investigations of the mechanisms that occur in aluminum‐ion batteries.

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“…This has opened up new challenges as well as opportunities in the realization of more efficient aqueous ZIBs (AZIBs) with a variety of other cathode materials . Although other chemistries based on Al/Al 3+ and Mg/Mg 2+ have been proposed, the Zn/Zn 2+ systems are considered to be the leading candidate due to the high theoretical capacity (820 mAh g −1 ), low redox potential (−0.76 V vs standard hydrogen electrode [SHE]), natural abundance, and low cost of Zn metal …”

Section: Introductionmentioning

confidence: 99%

Dendrite Growth Suppression by Zn²⁺‐Integrated Nafion Ionomer Membranes: Beyond Porous Separators toward Aqueous Zn/V₂O₅ Batteries with Extended Cycle Life

2019

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The dendritic/irregular growth of zinc deposits in the anode surface is often considered as a major intricacy limiting the lifespan of aqueous zinc‐ion batteries. The effect of separators on the evolution of the surface morphology of the anode/cathode is never thoroughly studied. Herein, for the first time, the efficacy of the Zn2+‐integrated Nafion ionomer membrane is demonstrated as a separator to effectively suppress the growth of irregular zinc deposits in the metallic anode of an aqueous Zn/V2O5 battery. The Zn2+‐ions coordinated with the SO3− moieties in Nafion result in a high transference number of the Zn2+ cation, all the while facilitating a high ionic conductivity. The Zn2+‐integrated Nafion membrane enables the Zn/V2O5 cell to deliver a high specific capacity of 510 mAh g−1 at a current of 0.25 A g−1, which is close to the theoretical capacity of anhydrous V2O5 (589 mAh g−1). Moreover, the same cell exhibits an excellent cycling stability of 88% retention of the initial capacity even after 1800 charge–discharge cycles, superior to that of the Zn/V2O5 cells comprising conventional porous separators.

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An aluminium battery operating with an aqueous electrolyte

Cited by 78 publications

References 20 publications

Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

The Compensation Effect Mechanism of Fe–Ni Mixed Prussian Blue Analogues in Aqueous Rechargeable Aluminum‐Ion Batteries

Dendrite Growth Suppression by Zn²⁺‐Integrated Nafion Ionomer Membranes: Beyond Porous Separators toward Aqueous Zn/V₂O₅ Batteries with Extended Cycle Life

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An aluminium battery operating with an aqueous electrolyte

Cited by 78 publications

References 20 publications

Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

The Compensation Effect Mechanism of Fe–Ni Mixed Prussian Blue Analogues in Aqueous Rechargeable Aluminum‐Ion Batteries

Dendrite Growth Suppression by Zn2+‐Integrated Nafion Ionomer Membranes: Beyond Porous Separators toward Aqueous Zn/V2O5 Batteries with Extended Cycle Life

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Product

Resources

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Dendrite Growth Suppression by Zn²⁺‐Integrated Nafion Ionomer Membranes: Beyond Porous Separators toward Aqueous Zn/V₂O₅ Batteries with Extended Cycle Life